研究生: |
張偉軒 Wei-Hsuan Chang |
---|---|
論文名稱: |
應用於5G手持式裝置與防撞雷達系統之毫米波天線設計 Millimeter-Wave Antenna Design for 5G Handheld Device and Anti-Collision Radar System |
指導教授: |
楊成發
Chang-Fa Yang |
口試委員: |
廖文照
Wen-Jiao Liao 林健維 Jian-Wei Lin 陳文士 Wen-Shi Chen 戴易明 Yi-Ming Dai 王德順 De-Shun Wang |
學位類別: |
碩士 Master |
系所名稱: |
電資學院 - 電機工程系 Department of Electrical Engineering |
論文出版年: | 2016 |
畢業學年度: | 104 |
語文別: | 中文 |
論文頁數: | 97 |
中文關鍵詞: | 第五代行動通訊 、毫米波 、場型可重置天線 、防撞雷達系統 、波導槽孔陣列天線 |
外文關鍵詞: | 5G communication system, Millimeter-wave, Pattern reconfigurablesantenna, sAnti-Collision Radar System, Waveguide slot array antenna |
相關次數: | 點閱:803 下載:5 |
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本論文針對應用於第五代行動通訊手持式裝置之場型可重置天線以及應用於盲點偵測之車用防撞雷達天線進行研究。第一部分將提出兩款可重置功率分配電路,並與準八木天線和矩形貼片天線結合而形成場型可重置天線,其中該可重置電路可任意激發4支天線,使場型具有多達15種的變化,以依照使用情境選擇合適之場型,來滿足手持式裝置之訊號涵蓋需求。本研究針對此兩款可重置電路的匹配流程進行分析探討,以固定匹配方式即能使所提出場型可重置天線在36~40GHz毫米波頻帶內於所有操作狀態下皆有一定的頻寬,並且實測驗證整體天線輻射效果良好。第二部分則針對盲點偵測防撞雷達之應用,提出一款以基板整合波導為串列式饋入結構之槽孔陣列天線設計,並進行相關前端電路設計,如巴倫器、濾波器、直流阻隔器等,其中為改善前端電路對天線場型造成影響,本研究應用基板整合波導本身的特性、陣列編排的技巧並結合饋入形式,來進一步提升天線性能。
This thesis contains two parts. First part presents a pattern reconfigurable antenna operating in the 36~40 GHz band. It is projected to be used on handheld devices for future 5G wireless communications. The proposed design is a multi-antenna system, which comprises a reconfigurable power divider that excites one or multiple antennas according to system’s commands. The diversified antenna excitation combinations provide various radiation patterns to meet the wideband mobile communication need of the future 5G handset. The main challenge is to maintain a proper matching condition under different excitation configurations. In the proposed design, a simple matching circuit is employed to match all cases. A total of fifteen radiation patterns is provided with a four-antenna system. The second part is to design substrate integrated waveguide(SIW) slot array antenna for blind spot detection(BSD) application and further, cooperating with Alltek Marine Electronics Corp. (AMEC) carry out automotive collision avoidance radar system. Because propose antennas need to be integrated with radar module, we have to design some RF front end circuits to achieve system’s requirement, ex : balun, filter, and DC block. However these circuits will influence antenna’s performance, so in this study propose another antenna structure which take different way to feed to reduce RF front end circuits and make use of different arrange skill of array to solve aforementioned influence and upgrade antenna performance.
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